Filter cartridge having a filter within a filter, and an endplate sealing structure on an outer filter element

ABSTRACT

A filter within a filter cartridge design is described that includes a sealing structure on an endplate of an outer filter element. Generally, the sealing structure includes an annular flange on the endplate that can directly seal against an interior surface of a housing when the filter cartridge is assembled for use. During filtration, the annular flange prevents a working fluid from bypassing the outer filter element. The sealing flange can seal with the housing in a press fit engagement.

This application claims the benefit of U.S. Provisional Application Ser.No. 61/108,762, filed on Oct. 27, 2008, and titled “FILTER CARTRIDGEHAVING A FILTER WITHIN A FILTER, AND AN ENDPLATE SEALING STRUCTURE ON ANOUTER FILTER ELEMENT”, the entirety of which is incorporated herewith byreference.

FIELD

The disclosure herein generally relates to fluid filters and theirassemblies. More particularly, the present disclosure relates to afilter cartridge for a filter within a filter arrangement. An outerfilter element of the cartridge has an improved seal configuration,where a working fluid must first flow through the outer filter elementbefore reaching an inner filter element.

BACKGROUND

Fluid filters are widely known and used in various filtration systemsand applications, for instance where there is a need for particle and/orfluid separation from a working fluid in a protected system. As oneexample, fuel filtration systems for engines are well known and canemploy fluid filters that are aimed at water and particle separationfrom fuel. Filter cartridges in some of these filters have one filterelement with media to first coalesce water, and have another filterelement that has media to further filter the fuel, while the coalescedwater drains from the cartridge. In many cases, such media is arrangedin a concentric filter within a filter configuration, where the outerfilter element has the more coarse media to coalesce the water, and theinner filter element has the more fine media that can removeparticulates from the fuel, while the coalesced water drains out of thecartridge.

However, current filter within a filter designs can encounter problems.Avoiding problems is desired to provide effective filtration, to providewater removal efficiency, and to protect engine components.

Improvements can be made upon existing filter designs. Particularly,structural improvements can be made as to how cartridges having thefilter within a filter arrangement are sealed, so as to prevent aworking fluid from bypassing the outer filter element of the cartridgebefore reaching an inner filter element of the cartridge.

SUMMARY

The present disclosure generally relates to a filter within a filtercartridge design that includes a unique sealing structure on an endplateof an outer filter element. Generally, the sealing structure includes anannular flange on the endplate that can seal against an interior surfaceof a housing when the filter cartridge is assembled for use. Duringfiltration, the annular flange prevents a working fluid from bypassingthe outer filter element.

In one embodiment, a filter cartridge includes outer and inner filterelements having respective filtering media. The media of the outerfilter element is arranged around the media of the inner filter element,such that a space is defined therebetween. The media of the inner filterelement defines a space therein that is separate from the space betweenthe media. For example such a space can be in the range of 0.125″ to 1″per side. The outer filter element has a first endplate connected at oneend and a second endplate connected at an opposing end. The inner filterelement has a first endplate connected at one end and a second endplateconnected at an opposing end. The first endplate of the outer filterelement and the first endplate of the inner filter element are connectedin a fluid tight seal and define an outlet flow passage. This internalseal is needed to keep the unfiltered particles from by-passing thesecondary filter. This design creates a cylindrical surface to surfacecontact between the two adjoining endplates but can also be accomplishedthrough means of an elastomeric seal. The second endplate of the outerfilter element and the second endplate of the inner filter element areconnected and define a drain channel. The space between the media is influid communication with the drain channel and the space within theinner filter element is in fluid communication with the outlet flowpassage. The second endplate of the outer filter element includes asealing flange surrounding the drain channel.

In one embodiment, a filter housing includes an inner surface with amain filtration cavity and a reservoir cavity, defined by an inwardprotruding flange therebetween. The filter cartridge can be insertedinto the main filtration cavity, such that the sealing flange sealsagainst the inward protruding flange of the housing in a fluid tightseal to separate the filtration cavity from the reservoir cavity. In oneembodiment, the sealing flange and the inward protruding flange aresealed in a press fit engagement.

In one embodiment, the filter housing and filter cartridge includeconnection and seal structures on their external surfaces that allowmating to existing filter heads.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective exploded view of one embodiment of an assemblyof a filter cartridge and housing.

FIG. 2 is an end view of the filter cartridge and housing of FIG. 1.

FIG. 3 is a side sectional view of the filter cartridge and housing ofFIG. 1 taken from FIG. 2.

FIG. 4 is an opposite end view of the assembly of FIG. 1.

FIG. 5 is a side view of the housing of FIG. 1.

FIG. 6 is an end view of the housing of FIG. 1.

FIG. 7 is a side sectional view of the housing of FIG. 1 taken from FIG.6.

FIG. 8 is an exploded perspective view of the filter cartridge of FIG. 1showing an outer filter element and an inner filter element.

FIG. 9 is an end view of the filter cartridge of FIG. 1.

FIG. 10 is a side sectional view of the filter cartridge of FIG. 1 takenfrom FIG. 9.

FIG. 11 is a side view of the outer filter element of FIG. 8.

FIG. 12 is an end view of the outer filter element of FIG. 8.

FIG. 13 is a side sectional view of the outer filter element of FIG. 8taken from FIG. 12.

FIG. 14 is a perspective view of a first endplate of the outer filterelement of FIG. 8.

FIG. 15 is another perspective view of the first endplate of FIG. 14.

FIG. 16 is an end view of the first endplate of FIG. 14.

FIG. 17 is a side sectional view the first endplate of FIG. 14 takenfrom FIG. 16.

FIG. 18 is a perspective view of a second endplate of the outer filterelement of FIG. 8.

FIG. 19 is an end view of the second endplate of FIG. 18.

FIG. 20 is a side sectional view of the second endplate of FIG. 18 takenfrom FIG. 19.

FIG. 21 is a close-up view of a portion of the second endplate of FIG.18 taken from FIG. 20.

FIG. 22 is a perspective exploded view of the inner filter element ofFIG. 8.

FIG. 23 is an end view of the inner filter element of FIG. 8.

FIG. 24 is a side sectional view of the inner filter element of FIG. 8taken from FIG. 23.

FIG. 25 is a perspective view of a first endplate of the inner filterelement of FIG. 8.

FIG. 26 is an end view of the first endplate of FIG. 25.

FIG. 27 is side sectional view of the first endplate of FIG. 25 takenfrom FIG. 26.

FIG. 28 is a perspective view of a second endplate of the inner filterelement of FIG. 8.

FIG. 29 is an end view of the second endplate of FIG. 28.

FIG. 30 is a side sectional view of the second endplate of FIG. 28 takenfrom FIG. 29.

FIG. 31 is a side sectional view of the filter cartridge and housingassembled with a filter head.

FIG. 32 is a partial sectional view showing another embodiment of a sealinterface between the second endplate of the outer filter element andthe housing.

FIG. 33 is a partial sectional view showing another embodiment of a sealinterface between the second endplate of the outer filter element andthe housing.

FIG. 34 is a partial sectional view showing another embodiment of a sealinterface between the second endplate of the outer filter element andthe housing.

FIG. 35 is a partial sectional view showing another embodiment of a sealinterface between the second endplate of the outer filter element andthe housing.

FIG. 36 is a partial sectional view showing another embodiment of a sealinterface between the second endplate of the outer filter element andthe housing.

FIG. 37 is a partial sectional view showing another embodiment of a sealinterface between the second endplate of the outer filter element andthe housing.

FIG. 38 is a partial sectional view showing another embodiment of a sealinterface between the second endplate of the outer filter element andthe housing.

FIG. 39 is a partial sectional view showing another embodiment of a sealinterface between the second endplate of the outer filter element andthe housing.

FIG. 40 is a partial sectional view showing another embodiment of a sealinterface between the second endplate of the outer filter element andthe housing.

FIG. 41 is a partial sectional view showing another embodiment of a sealinterface between the second endplate of the outer filter element andthe housing.

FIG. 42 is a partial sectional view showing another embodiment of a sealinterface between the second endplate of the outer filter element andthe housing.

DETAILED DESCRIPTION

FIGS. 1-31 of the present disclosure generally relate to a filterhousing and filter cartridge assembly having a unique sealconfiguration, where an endplate of an outer filter element that sealsdirectly to an inner surface of the housing. In multiple phasefiltration, for example filter within a filter designs, the sealconfiguration and related structures described can prevent a workingfluid from bypassing the outer filter element before it reaches an innerfilter element. In engine systems, for example, the filter cartridge andhousing structures described herein can provide effective filtration ofa working fluid and protect engine components.

FIGS. 1-30 show one example of an assembly of a housing 10 and a filtercartridge 20. FIG. 31 shows the assembly connected to a filter head 120.In one embodiment, the assembly described can be employed as a fuelfilter assembly, which is intended to filter a fluid, for example dieselfuel, and remove water from the fluid before the fluid reaches aprotected system, for example a fuel injection pump and fuel injectors.Fuel filters and their uses are well known. For illustration purposesonly, the inventive concepts for a filter cartridge and housing designare described with respect to a fuel filter assembly and with respect tofiltration of fuel. However, it is to be realized that in appropriatecircumstances the concepts described herein can be used for workingfluids other than fuel. Likewise, in appropriate circumstances, theconcepts described herein can be applied to other types of filterassemblies that filter other types of fluids, for example lubrication,hydraulic, and other liquids, as well as air.

FIGS. 1-4 illustrate one embodiment of the filter cartridge 20 assembledtogether with the housing 10. The housing 10 has a generally open endthat the filter cartridge 20 can be inserted into. A water-in-fuel (WIF)sensor 100 and a drain valve 110 are connected at an opposite end of thehousing 10. WIF sensors can generate a signal that is sent to an enginecontrol unit (not shown), where the engine control unit can thengenerate a signal to indicate that the filter assembly needs to bechanged, serviced, or drained. The drain valve 110 is closed duringoperation but can be opened when draining is desired. WIF sensors anddrain valves are known and need no further description.

The assembly includes flow passages. An inlet 22 allows a working fluidto be filtered (e.g. fuel) to enter the assembly and an outlet 24 allowsfiltered fluid to exit the assembly. As shown, for example, the inlet 22is a gap between an outer perimeter of the filter cartridge 20 and aninner perimeter of the housing 10 (best shown in FIG. 2). A workingfluid can enter the inlet 22, flow through an outer filter element, flowthrough an inner filter element (inner and outer filter elementsdescribed in detail below), and exit the outlet 24 (see arrows of FIG.3).

In one embodiment, the housing 10 and the filter cartridge 20 includeouter connective and seal structures on their external surfaces thatallow mating to filter head designs currently being used. As shown, forexample, the housing 10 includes a threaded portion 12 and groove 14 foran o-ring or gasket seal and the filter cartridge 20 includes a gasketface seal 16. Such a configuration can be used to connect and seal theassembly to existing filter head designs, for example, fuel filter headsin other products of Cummins Filtration, Inc. (the Assignee of thepresent application), such as the MACH-2 fuel filter. See also e.g. thefilter head 120 in FIG. 31.

As shown in FIG. 3, the housing 10 includes a reservoir cavity 18 thatis sealed from the general filtration cavity that the filter cartridge20 resides in. In general, the filter cartridge includes an outer filterelement with a sealing flange on an endplate that directly seals with aninterior surface of the housing, which is described in detail below.

With particular reference to the housing 10, FIGS. 5-7 show the housing10 alone. The housing 10 includes an inner surface with a mainfiltration cavity 11 and the reservoir cavity 18, defined by an inwardprotruding flange 17 therebetween. The inward protruding flange 17defines the separate cavities, where the reservoir cavity 18 can be anarrower portion than the main filtration cavity 11. In one embodiment,the protruding flange 17 is a U-shaped lip in section (best shown inFIG. 7) that is disposed about the inner surface of the housing 10. Asshown and described, the filter cartridge 20 can be inserted into themain filtration cavity 11 and has a sealing flange that can be sealedagainst the inward protruding flange 17 of the housing 10 in a fluidtight seal (sealing flange further described below). The seal betweenthe filter cartridge 20 and the protruding flange 17 separates thefiltration cavity 11 from the reservoir cavity 18. The housing 10further includes an end ridge 13 that can engage rests of the filtercartridge 20 (rests further described below).

Openings 102 and 104 respectively are in fluid communication with thereservoir cavity 18, and allow connection of the drain valve 110 and theWIF sensor 100, which can be connected by a threaded engagement.

With particular reference to the filter cartridge 20, FIGS. 8-10 showthe filter cartridge 20 with an outer filter element 30 and an innerfilter element 40.

In one embodiment, the outer and inner filter elements 30, 40 haverespective filtering media 36, 46 (see FIGS. 13 and 22 respectively anddescribed below). As one example, the media is a pleated material.Filtering media is well known, and filtering media in fuel filtration iswell known and need not be further described. In some examples, thefiltering media 36 of the outer filter element 30 is a coarser material(e.g. water coalescing) than the filtering media 46 of the inner filterelement 40, which can employ a material more suited for fine filtration(e.g. particulate matter).

As shown in FIG. 10, for example, the media of the outer filter element30 is arranged around the media of the inner filter element 40, suchthat a space 38 is defined therebetween. For example such a space (e.g.38) can be in the range of 0.125″ to 1″ per side. The media of the innerfilter element 40 defines a space 48 therein that is separate from thespace 38 between the media. The outer filter element 30 has a firstendplate 32 connected at one end and a second endplate 34 connected atan opposing end. The inner filter element 40 has a first endplate 42connected at one end and a second endplate 44 connected at an opposingend. In some embodiments, the endplates 32, 34, 42, 44 of the outer andinner filter elements 30, 40 are embedded, bonded or otherwise fixed tothe filter media 36, 46 to create fluid tight seals at the ends whichthey are connected.

The first endplate 32 of the outer filter element 30 and the firstendplate 42 of the inner filter element 40 are connected in a fluidtight seal and define an outlet flow passage (e.g. outlet 24). Thesecond endplate 34 of the outer filter element 30 and the secondendplate 44 of the inner filter element 40 are connected and define adrain channel therethrough (see arrows of FIG. 10). The space 38 betweenthe media is in fluid communication with the drain channel and the space48 within the inner filter element 40 is in fluid communication with theoutlet flow passage. In some examples, the respective endplates 32, 42and 34, 44 can be connected through a press or interference fit.

The second endplate 34 of the outer filter element 40 includes oneembodiment of a sealing flange 50 which surrounds the drain channel. Asdiscussed above, the filter cartridge 20 can be inserted into the mainfiltration cavity 11 of the housing 10, such that the sealing flange(e.g. sealing flange 50) seals against the inward protruding flange 17of the housing 10 in a fluid tight seal to separate the filtrationcavity 11 from the reservoir cavity 18.

With particular reference to the outer filter element 30, FIGS. 11-13show the outer filter element 30 alone and FIGS. 14-21 respectively showits first and second endplates 32, 34. The first endplate 32 isconnected to one end of the media 36 and the second endplate 34 isconnected to the opposite end of the media 36.

The first endplate 32 includes at least one rest member 52 disposedabout its outer perimeter. In the example shown, the first endplate 52for example can have a plurality of rest members 52. The rest members 52are constructed and arranged as stepped or lipped protrusions that canreleasably engage the end ridge of the housing 10.

The first endplate 32 also includes a groove 54 that holds the seal 16(e.g. gasket or o-ring seal) that can seal to a filter head.

In the example shown, an inner annular flange 56 extends partially intothe area surrounded by the media 36 and defines an opening through thefirst endplate 32. The flange 56 connects with a flange 66 of the firstendplate 42 (further described below) of the inner filter element 40 tocreate the outlet flow passage (e.g. outlet 24). In one preferredexample, the flange 56 is connected to the flange 66 of the firstendplate 42 in a fluid tight seal, so as to maintain separation of fluidto be filtered from filtered fluid (e.g. ‘clean’ side from ‘dirty’side).

FIGS. 14-17 show the first endplate 32 of the outer filter element 30alone.

The second endplate 34 includes the sealing flange 50. As discussed, thesealing flange 50 and the inward protruding flange 17 seal against eachother when the filter cartridge 20 is inserted into the housing 10. Inone embodiment, such as shown, the second endplate 34 and sealing flange50 may be but are not necessarily limited to a bottom endplate and sealconfiguration for the filter cartridge 20 or at the fluid outlet end ofthe filter cartridge 20.

In one embodiment, the sealing flange 50 and the inward protrudingflange 17 are sealed in a press or interference fit type sealingengagement. In one preferred example as shown, the seal arrangement is aradial/annular seal configuration between the filter cartridge 20 andthe housing 10 and, in some cases, the seal arrangement may be along ashelf-like configuration with respect to the protruding flange (seerespectively FIGS. 32-42 below). In some examples, either or both of theinward protruding flange 17 (e.g. inner portion of the U-shape) and thesealing flange 50 can be deflectable or deformable to provide a suitablepress-fit seal against each other. The press fit seal can be a compositeon composite seal, such as plastic on plastic. In one embodiment, theendplate 34 and the housing 10 are constructed of composite materials,such as plastic.

The second endplate 34 further includes an inner annular flange 58. Theinner annular flange 58 provides an opening through the second endplate34 and its surface connects to the second endplate 44 of the innerfilter element 40. In one embodiment, the inner annular flange 58includes a barb or catch 58 a (best shown in FIG. 21) that retains thesecond endplate 44 of the inner filter element 40.

FIGS. 18-21 show the second endplate 34 of the outer filter element 30alone.

With particular reference to the inner filter element 40, FIGS. 22-24show the inner filter element 40 alone and FIGS. 25-30 respectively showits first and second endplates 42, 44. The first endplate 42 isconnected to one end of the media 46 and the second endplate 44 isconnected to the opposite end of the media 46.

The first endplate 42 includes the inner annular flange 66. In theexample shown, the inner annular flange 66 extends partially into thearea (e.g. space 48) surrounded by the media 46 and defines an openingthrough the first endplate 42. As described, the flange 66 connects withthe flange 56 of the first endplate 32 (further described below) of theouter filter element 30 to create the outlet flow passage (e.g. outlet24). In one preferred example, the flange 66 is connected to the flange56 of the first endplate 32 in a fluid tight seal, so as to maintainseparation of fluid to be filtered from filtered fluid (e.g. ‘clean’side from ‘dirty’ side).

FIGS. 25-27 show the first endplate 42 of the inner filter element 40alone.

The second endplate 44 includes a planar surface 62 with a protrusion 64thereon that closes and seals one end of the space 48 within the secondmedia 46.

The second endplate 44 includes legs 68 extending from one side of thesecond plate member 44. In one embodiment, the legs 68 are disposed onthe side opposite the planar surface 62. In one embodiment, legs 68extend beyond an outer perimeter of the second endplate 44. In operationfor example, legs 68 provide a standoff feature for the second endplate44 and cooperate with the inner annular flange 58 of the second endplate34 of the outer filter element 30. For example, the legs 68 engage thebarb or catch 58 a of the second endplate 34 of the outer filter element30, and can help retain the second endplate 44 of the inner filterelement 40. Further, the legs 68 and inner annular flange 58 create thedrain channel(s) by allowing a gap for fluid to drain from the space 38between the media 36, 46 into the reservoir cavity 18 (e.g. waterseparated from fuel). See e.g. arrows in FIG. 10. and FIG. 2.

FIGS. 28-30 show the second endplate 44 of the inner filter element 40alone.

FIG. 31 shows the assembly of the filter cartridge 20 and housing 10connected to a filter head 120. FIG. 31 shows one example where theassembly of the filter cartridge 20 and housing 10 can connect and sealwith existing filter heads being used. In the example shown in FIG. 31,the filter head 120 is connectable to the housing 10 through a threadedengagement with threads 12 of the housing 10 and a sealing engagementwith the sealing groove 14 (o-ring inside as shown in FIG. 31). Flowthrough the filter head 120 can enter the line as shown on the right ofthe filter head 120 which is in fluid communication with the inlet 22,and fluid flow can exit the line as shown at the left of the filter head120 which is in fluid communication with the outlet 24 (see arrows).

In general, a filter cartridge has been described above that includes anouter filter element with a sealing flange on an endplate that directlyseals with an interior surface of the housing. In the embodimentdescribed above, for example, the filter cartridge 20 can be insertedinto the housing 10, and has a sealing flange that can be sealed againstthe inward protruding flange 17 of the housing 10 in a fluid tight seal.The seal between the filter cartridge 20 and the protruding flange 17separates the filtration cavity 11 from the reservoir cavity 18.

With further reference to the embodiment described above, the sealingflange 50 and the inward protruding flange 17 are sealed in a press orinterference fit type sealing engagement. In one preferred example asshown, the seal arrangement a radial/annular seal configuration betweenthe filter cartridge 20 and the housing 10. In some examples, either orboth of the inward protruding flange 17 (e.g. inner portion of theU-shape) and the sealing flange 50 can be deflectable or deformable toprovide a suitable press-fit seal against each other. The press fit sealcan be a composite on composite seal, such as plastic on plastic. In oneembodiment, the endplate 34 and the housing 20 are constructed ofcomposite materials, such as plastic.

It will be appreciated that the embodiment shown in FIGS. 1-31 is notmeant to be limiting to the specific seal interface shown between theendplate 34 and housing 10. Other configurations may be contemplated invarious alternatives, for example as illustrated in FIGS. 32-42. Similarconcepts may also apply to FIGS. 32-42 as in FIGS. 1-31, such as theseal arrangement being a radial/annular seal configuration between thefilter cartridge 20 and the housing 10, and the seal arrangement alsobeing, in some cases as appropriate, along a shelf-like configurationwith respect to the protruding flange 17 of the housing. Likewise,either or both of the inward protruding flange 17 (e.g. inner portion ofthe U-shape) and the alternative sealing flanges described in FIGS.32-42, where appropriate, can be deflectable or deformable to provide asuitable press-fit seal against each other. As with the embodiment ofFIGS. 1-31, the seal shown in FIGS. 32-42 can be a press fit seal, suchas a composite on composite seal (e.g. plastic on plastic) or athermoplastic/elastomer material on plastic seal. As above, the endplate34 and the housing 10 shown in FIGS. 32-42 also can be constructed ofcomposite materials, such as plastic.

With specific reference to FIGS. 32-42, such alternative sealinginterfaces are described, where alternative sealing flanges seal to atleast one of the inner surface of the inward protruding flange 17 and/orwithin a groove defined by the inward protruding flange 17.

FIG. 32 is a partial sectional view showing another embodiment of a sealinterface between the second endplate 34 of the outer filter element andthe housing 10. The endplate 34 includes the inner annular flange with abarb or catch 58 a, but with a modified outer flange 150. As shown, theflange 150 includes a seal member 152, which may be an o-ring, disposedon its outer surface. The seal member 152 engages the inner surface ofthe inward protruding flange 17 to seal with the housing. As shown, theseal member 152 is an o-ring, however it will be appreciated that anysuitable seal member may be employed. As another example, the sealmember may be an appropriate gasket structure. As above in FIG. 20, forexample, the endplate 34 may also have recesses 154 that allow theflange 150 to be more easily deformed/deflected when press fitting theendplate 34 to the housing.

FIG. 33 is a partial sectional view showing another embodiment of a sealinterface between the second endplate 34 of the outer filter element andthe housing 10. The endplate 34 includes the inner annular flange with abarb or catch 58 a, but with a modified outer flange 250. As shown, theflange 250 is structured as a flexible finger that seals to the innersurface of the inward protruding flange 17 of the housing 10. Theflexible finger as shown extends downwardly and then away from thecenter of the endplate 34 (e.g. toward the inward protruding flange 17),and may be deflectable for example along its outer curve changing fromdownward and then away from the endplate 34 (e.g. toward the flange 17).

FIG. 34 is a partial sectional view showing another embodiment of a sealinterface between the second endplate 34 of the outer filter element andthe housing 10. The endplate 34 includes the inner annular flange with abarb or catch 58 a, but with a modified outer flange 350. As shown, theflange 350 is structured as a curved overlap that curls over the top rimof the inward protruding flange 17. The flange 350 on one side partiallyextends into a groove 17 a of the inward protruding flange 17. When thefilter cartridge is inserted into the housing, the press fit can bealong the top rim of the inward protruding flange 17 and the undercurvature of the flange 350. The under curvature is configured as thesealing surface.

FIG. 35 is a partial sectional view showing another embodiment of a sealinterface between the second endplate 34 of the outer filter element andthe housing 10. The endplate 34 includes the inner annular flange with abarb or catch 58 a, but with a modified outer flange 450. As shown, theflange 450 is structured as a deformable grooved finger. The flange 450can be inserted downward into a groove 17 a of the inward protrudingflange 17. The flange 450 extends into the groove 17 a, where thegrooved finger structure has a width that slightly larger than the widthof the groove to create a press fit seal when the endplate 34 engagesthe housing 10. In one embodiment, the fingered structure has twofingers 452 commonly connected to the endplate 34 with a groovetherebetween to allow some deformation during connection.

FIG. 36 is a partial sectional view showing another embodiment of a sealinterface between the second endplate 34 of the outer filter element andthe housing 10. The endplate 34 includes the inner annular flange with abarb or catch 58 a, but with a modified outer flange 550. As shown, theflange 550 is a flexible finger that seals against the inside wall ofthe housing 10. The flange 550 can be inserted downward into a groove 17a of the inward protruding flange 17. The flange 550 extends downwardand away from a center of the endplate 34. In the embodiment shown, theend of the flange 550 curls toward the inner wall of the housing 10.When the endplate 34 engages the housing 10, the end of the flange 550presses against the inner wall of the housing 10 to create a seal.

FIG. 37 is a partial sectional view showing another embodiment of a sealinterface between the second endplate 34 of the outer filter element andthe housing 10. The endplate 34 includes the inner annular flange with abarb or catch 58 a, but with a modified flange 650. As shown, the flange650 is a flexible finger to seals to the top rim of the inwardprotruding flange 17. Similar to FIG. 33, the flange 650 extendsdownward and away from the center of the endplate 34. The flexiblefinger may be deflectable for example along its outer curve whenchanging from downward and then toward the inner wall of the housing 10(e.g. away from the center of the endplate). The flexible finger has anunder surface configured as the sealing surface.

FIG. 38 is a partial sectional view showing another embodiment of a sealinterface between the second endplate 34 of the outer filter element andthe housing 10. The endplate 34 includes the inner annular flange with abarb or catch 58 a, but with a modified outer flange 750. As shown, theflange 750 seals against the inward protruding flange on a surfacewithin a groove 17 a. The flange 750 extends downward and then upward atan angle, such that when the endplate 34 is engaged with the housing 10,the flange 750 seals with the inward protruding flange 17 on the surfacewithin the groove 17 a. The flange 750 may be flexible along its changeof direction from downward to upward at an angle. The flange 750 has anunder surface configured as a sealing surface.

FIG. 39 is a partial sectional view showing another embodiment of a sealinterface between the second endplate 34 of the outer filter element andthe housing 10. The endplate 34 includes the inner annular flange with abarb or catch 58 a, but with a modified outer flange 850. As with FIG.38, the flange 850 as shown seals against the inward protruding flange17 on a surface within a groove 17 a. The flange 850 extends downwardand is curved toward the center of the second endplate 34 (e.g. towardthe inward protruding flange 17), such that when the endplate 34 isengaged with the housing 10, the flange 850 seals with the inwardprotruding flange 17 on the surface within the groove 17 a. The flange850 may be flexible along its curvature and includes an end distalsurface as the sealing surface.

FIG. 40 is a partial sectional view showing another embodiment of a sealinterface between the second endplate 34 of the outer filter element andthe housing 10. The endplate 34 includes the inner annular flange with abarb or catch 58 a, but with a modified outer flange 950. As shown, theflange 950 is structured as an attached elastomer member on an undersideof the endplate 34. The elastomer member is a flexible material. Theflange 950 extends downward onto the top rim of the inward protrudingflange 17. The flange 950 in some embodiments such as shown includes agroove 952 as a sealing surface that can receive the top rim. When thefilter cartridge is inserted into the housing 10, the endplate 34 canengage the inward protruding flange 17 of the housing in a press fitsealing engagement.

FIG. 41 is a partial sectional view showing another embodiment of a sealinterface between the second endplate 34 of the outer filter element andthe housing 10. The endplate 34 includes the inner annular flange with abarb or catch 58 a, but with a modified outer flange 1050. As shown, theflange 1050 is similar to the flange 50, but rather than sealing to theside surface of the inward protruding flange, the flange 1050 extendsinto and seals to a groove 17 a of the inward protruding flange 17, suchas in a direct plastic to plastic interface.

FIG. 42 is a partial sectional view showing another embodiment of a sealinterface between the second endplate 34 of the outer filter element andthe housing 10. The endplate 34 includes the inner annular flange with abarb or catch 58 a, but with a modified outer flange 1150. As shown, theflange 1150 is similar to the flange 1050, but the flange 1150 includesan additional elastomer member 1152 on the end tip of the flange 1150.The flange 1150 extends into and seals to a groove 17 a of the inwardprotruding flange 17, through the elastomer member 1152.

As discussed, the improved sealing structure herein is useful forexample in filter within a filter arrangements directed towardsmulti-phase filtration (e.g. separation of water and particulates fromfuel in engines), where a working fluid is prevented from bypassing theouter filter element before it reaches an inner filter element. Theinventive concepts herein can provide effective filtration andprotection of engine components.

While the above is a complete description of the preferred embodimentsof the invention, various alternatives, modifications, and equivalentsmay be used. Therefore, the above description should not be taken aslimiting the scope of the invention which is defined by the appendedclaims.

1. A filter cartridge comprising: an outer filter element; and an innerfilter element, the outer and inner filter elements each have arespective filtering media, the media of the outer filter element isconcentrically arranged around the media of the inner filter element, afirst space is defined between the outer and inner filter elements, anda second space is defined within the inner filter element, the outerfilter element has a first endplate connected at one end and a secondendplate connected at an opposing end, and the inner filter element hasa first endplate connected at one end and a second endplate connected atan opposing end, the first endplate of the outer filter element and thefirst endplate of the inner filter element are connected in a fluidtight seal and define an outlet flow passage, the second endplate of theouter filter element and the second endplate of the inner filter elementdirectly contact each other and define a drain channel, the first spacebetween the filtering media is in fluid communication with the drainchannel, and the second space within the inner filter element is influid communication with the outlet flow passage, and wherein the secondendplate of the outer filter element includes a sealing flangesurrounding the drain channel.
 2. The filter cartridge of claim 1,wherein the first endplate of the outer filter element and the firstendplate of the inner filter element are connected in a press fitarrangement, and the second endplate of the outer filter element and thesecond endplate of the inner filter element are connected in a press fitarrangement.
 3. The filter cartridge of claim 1, wherein the firstendplate of the outer filter element includes at least one rest memberdisposed at its outer perimeter, the rest member constructed as astepped protrusion.
 4. The filter cartridge of claim 1, wherein thefirst endplate of the outer filter element includes an inner annularflange that extends into the second space defined within the innerfilter element, and the first endplate of the inner filter elementincludes an inner annular flange that extends into the second spacedefined within the inner filter element, the inner annular flanges areconnected in a fluid tight seal and create the outlet flow passage. 5.The filter cartridge of claim 1, wherein the second endplate of theouter filter element and the sealing flange are arranged as a bottomendplate structure of the cartridge.
 6. The filter cartridge of claim 1,wherein the sealing flange is a deflectable structure.
 7. The filtercartridge of claim 1, wherein the sealing flange includes a groove and aseal member disposed within the groove.
 8. The filter cartridge of claim1, wherein the sealing flange is a flexible finger, the flexible fingerextends downwardly from the second endplate of the outer filter elementand then away from a center of the second endplate, the sealing flangebeing deflectable along an outer curve changing from downward to awayfrom the second endplate.
 9. The filter cartridge of claim 1, whereinthe sealing flange is structured as a curved overlap having anundercurve configured as a sealing surface.
 10. The filter cartridge ofclaim 1, wherein the sealing flange is a deformable grooved finger, thedeformable grooved finger having a two finger structure commonlyconnected to the second endplate of the outer filter element with agroove between the two fingers.
 11. The filter cartridge of claim 1,wherein the sealing flange is a flexible finger, the flexible fingerextends downwardly from the second endplate of the outer filter elementand then away from a center of the second endplate, the sealing flangebeing deflectable along an outer curve changing from downward to awayfrom the second endplate, and has an under surface configured as asealing surface.
 12. The filter cartridge of claim 1, wherein thesealing flange extends downward from the second endplate of the outerfilter element and then upward at an angle toward a center of the secondendplate, the sealing flange being deflectable along a change ofdirection from downward to upward at an angle relative to the secondendplate, and has an under surface configured as a sealing surface. 13.The filter cartridge of claim 1, wherein the sealing flange extendsdownward from the second endplate of the outer filter element and has acurvature toward a center of the second endplate, the sealing flangebeing deflectable along the curvature and has an end distal surfaceconfigured as a sealing surface.
 14. The filter cartridge of claim 1,wherein the sealing flange is structured as an attached elastomer memberon an underside of the second endplate of the outer filter element, andhas a groove as a sealing surface.
 15. The filter cartridge of claim 1,wherein the sealing flange includes an elastomer member disposed on anend tip of the flange.
 16. A filtration assembly comprising a filtercartridge within a housing: the filter cartridge including an outerfilter element and an inner filter element, the outer and inner filterelements each have a respective filtering media, the media of the outerfilter element is concentrically arranged around the media of the innerfilter element, such that a space is defined between the outer and innerfilter elements, and a space is defined within the inner filter element,the outer filter element has a first endplate connected at one end and asecond endplate connected at an opposing end, and the inner filterelement has a first endplate connected at one end and a second endplateconnected at an opposing end, the first endplate of the outer filterelement and the first endplate of the inner filter element are connectedin a fluid tight seal and define an outlet flow passage, the secondendplate of the outer filter element and the second endplate of theinner filter element are connected and define a drain channel, the spacebetween the filtering media is in fluid communication with the drainchannel, and the space within the inner filter element is in fluidcommunication with the outlet flow passage, and the second endplate ofthe outer filter element includes a sealing flange surrounding the drainchannel; and the housing has a generally open end where the filtercartridge can be inserted, a gap between an outer perimeter of thefilter cartridge and an inner perimeter of the housing at the open enddefines an inlet flow passage, the housing includes a reservoir cavityand a filtration cavity defined by an inward protruding flange, theinward protruding flange is configured to seal against the sealingflange of the second endplate of the outer filter element, to fluidlyseparate the reservoir cavity and the filtration cavity.
 17. Thefiltration assembly of claim 16, wherein the inward protruding flange isa U-shaped lip disposed about an inner surface of the housing, theU-shaped lip defining a groove, where the sealing flange is sealableagainst at least one of a surface outside of the groove of the U-shapedlip and an inner surface of the groove.
 18. The filtration assembly ofclaim 16, wherein the sealing flange of the filter cartridge and theinward protruding flange of the housing are sealed in a plastic toplastic press fit arrangement.
 19. The filtration assembly of claim 16,wherein at least one of the sealing flange of the filter cartridge andthe inward protruding flange of the housing is a deformable material.20. The filtration assembly of claim 16, wherein the first endplateincludes at least one rest member disposed at its outer perimeter, therest member constructed as a stepped protrusion that rest on an endridge of the housing.
 21. The filter cartridge of claim 1, wherein thesecond endplate of the outer filter element includes an inner annularflange that provides an opening therethrough, the second endplate of theinner filter element includes legs extending into the opening, engagingthe inner annular flange of the second endplate of the outer filterelement to define the drain channel.
 22. The filter cartridge of claim1, wherein the second endplate of the outer filter element includes afirst face attached to the filtering media and a second face oppositethe first face, the sealing flange extending from the second face.